JP2010535945A5 - - Google Patents

Description

Method for stabilizing a strip with a coating guided between air knife nozzles with melt-dip coating and melt-dip coating equipment

The present invention relates to a method for stabilizing a strip with a coating guided between air knife nozzles of a melt-dip coating equipment and to a suitable melt-dip coating equipment. In this case , a stabilizing force is exerted on the strip according to the detected strip position by means of a coil acting downstream of the air knife nozzle in the strip travel direction and acting on the steel strip penetrating electromagnetically without contact.

Electromagnetic strip stabilization is based on the principle of induction, it generates perpendicular to the ferromagnetic steel strip which draws the magnetic field defined. Thus, the steel strip state can be changed without contact between the electromagnetic derivative (electromagnets) the two opposite positions. Such a system is known in a different structure. These systems are used , for example , on the top of so-called air knife nozzles in the coating area , in the case of melt-dip coating equipment . Different coordination and control concepts are known. (For example, German Patent Application Publication No. 105005060058 [Patent Document 1] and International Application Publication No. 2006/006911 [Patent Document 2])

Air knife nozzles are used in steel strip melt dipping coating equipment to obtain a defined amount of coating media on the strip surface. Quality of the coating (coating uniformity, thickness precision, homogenous surface gloss) depends on the critically strip motion in uniformity and nozzle area of the air knife nozzle medium (e.g. air or nitrogen). This strip motion is caused by the melt-dip coating equipment , either by the non-circularity of the rolls or by, for example, the impact of air in the cooling tower region. The strip movement increases the air knife nozzle, coating quality or coating uniformity of the steel strip that penetrates is reduced.

By using a strip stabilization system connected downstream in the strip travel direction, the strip motion occurring inside the air knife nozzle can be damped or reduced, thus improving the coating accuracy and coating uniformity of the liquid metal. Achieved on the strip. This is, for example, an electromagnetic action actuator, the actuator, and adversely on the steel strip passing through the attracted force without contact, thereby changing the strip state.

In known systems, depending on the structure, on the basis of the strip stabilizing unit connected downstream of the air knife nozzle in strip running direction, for the strip movement in the air knife nozzle, occurs reduced action of the control. Sedation vibrations, within the strip stabilizer at the top of the air knife nozzle, is performed by a strip stabilizing coils with a higher efficiency. However, in the region of the nozzle, the action has been expressly limited by the distance increasing between the nozzle and the stabilization unit. In this case, the position of the strip stabilization part is confirmed according to structural facts without describing the physical dependence. Therefore, the goal of all applications, only possible strip stabilizing unit while positioned near the air knife nozzle, is not considered the relationship between the working and the interval.

German Patent Application No. 105005060058 International Application Publication No. 2006/006911

The object of the invention is therefore to improve the strip stabilization in the area of the air knife nozzle.

This problem is solved according to the invention by the method according to claim 1. This is because the (action) interval of the strip stabilization section from the air knife nozzle is adjusted to a value equal to or less than the interval threshold value, and the interval threshold value is calculated as a function of the strip width considering the factor phi. , characterized in that it is calculated as a function of the strip thickness and the strip tension.

Strip position is measured quantity is within the range of the original specification, it presents the temporal and / or location changes in the strip spacing against the side of the straight reference line with respect to the strip running direction. That is, the strip position, presents a strip-shaped and / or vibration behavior thereof as a function of time.

Concept strip stabilization, within the original specification two essential aspect encompasses; means smoothness while the strip-shaped strip stabilization corrugated, in other vibration of this concept strip Means attenuation. Both the viewpoint of the strip stabilization may be achieved by in independently or in combination with each other, or simultaneously suitable control circuit.

Essentially advantage of limitations that sought-apart, both in view of the time of adjusting the spacing value under the calculable interval threshold, a better effect is significant, sought to be obtained strive strip stabilized by the present invention To be achieved for. In contrast, the effect of the strip stabilization, is reduced or clearly when there is a gap on the distance threshold value, or strip, despite the stabilization control unstable than without (opposite effect) Control Become.

Interval is and even ideally zero, i.e., if the strip stabilizer is Ru are arranged at the height of the air knife is ideal, because the strip stabilizer is, directly to the air knife nozzle act in height, because the strip is Ru is optimally stably held during the measurement process. However, this arrangement is, usually can not be realized on the basis of the structure technically location deficiency. Accordingly, spacing, but it should be small adjustments as possible, up to even, should be adjusted to a value of which can be calculated interval threshold by the present invention.

The electromagnetic force is transmitted by a coil array positioned oppositely in pairs on the side surfaces of each strip, and the distance from the air knife nozzle of the coil array can be changed.

In particular, the method according to the invention, the strip position is measured within the coil arrangement, moreover, is determined by the spatial proximity of the coil arrangement.

Additionally, the strip location can be measured at the top and bottom of the coil arrangement.

According to the configuration of the present invention, each strip side and are arranged a plurality of coils, coil located outside each of which is parallel to adjustably arranged with respect to the plane of the strip on the strip edge that penetrates . This sequence is preferred in particular, to enable optimum action during the smoothing of the strip shape.

Distance from the air knife nozzle strip stabilizer referred to as a strip stabilizing unit for short in the following, the in the case of wide strip width (B> 1400 mm) does not exceed the strip width. For narrow strips (B <1400 mm) , spacings up to 1.75 times the strip width are allowed. This spacing results from the principle of Staint-Venant, which, for example, against on a fixed steel strip, with intervals of forces acting to increase the action of the force, means reducing the total state .

Basic for the solution according to the present invention is the positioning of the strip stabilizing unit for air knife nozzle in consideration of the stress mechanisms.

Effect of gradual load application in the load system given only occurs in a small region around the load application point on the principle of Staint-Venant. Due to the force guidance, the irregularly distributed force distribution is lost very quickly. This principle is typically used in the strength calculation that defines the dimensions of the component and is here used for the strip stabilization action in the air knife nozzle region.

Sufficient effect in order to achieve for the strip shape and the strip movement (vibration) in the air knife nozzle, i.e., to change them decisively, or to attenuate, consistent with the principles of Staint-Venant, spacing between stabilizing action and air knife nozzle are either selected on the confirmation region, or does not exceed the maximum value in the form of a distance threshold value. In this case , the distance, ie the length of the steel strip that can be expected to act by the strip stabilizer, must be selected based on the following rules:
Interval ≤ interval threshold = phi * characteristic length
However, Phi = function (strip thickness, strip tension)

The above problems are further solved by the required melt dipping coating equipment. This spacing (action) of the strip stabilizing unit from an air knife nozzle, is adjusted to the following values interval threshold, the distance threshold value is, the strip width in consideration of factors phi is a function of the strip thickness and the strip tension characterized in that it is calculated as a function.

  The advantages of this equipment are consistent with the advantages listed for the required method.

  The solution according to the invention will now be described in detail with reference to the drawings.

1 schematically shows an arrangement of strip stabilizing coils. Fig. 4 shows the formation of a strip. The arrangement of nozzle beams is schematically shown. 1 shows a strip stabilization system. The dependence of strip width factor phi is shown. It shows the relationship between the distance between the strip stabilizer from the strip speed and air knife nozzle.

The arrangement of the strip stabilization part ( strip stabilization coil 1 ) and the air knife nozzle is in principle apparent from FIG.

According to the Venant principle , the spacing threshold is approximately the strip width for wide steel strips that penetrate, and up to 1.75 times the strip width for narrow strips (see FIG. 5). ) At larger intervals , the action of the strip stabilization part ( strip stabilization coil 1 ) is very limited considering the smoothness of the strip shape (horizontal arc, S shape, see FIG. 2), or Large intervals are no longer recognizable.

In that case, the force working point of the strip stabilization unit, in order to exert a sufficient effect on the strip deformed portion such as horizontal arc of decreasing example, located too far from the nozzle lip. Furthermore, it has been pointed out by measurement and simulation that the vibration effect of the nozzle gap (attenuation of the amplitude of the strip vibration) also depends on the distance of the force action point with respect to the nozzle gap, which is the working place.

This results in the following relationship:
Spacing ≤ Phi (Strip thickness, strip tension) * Strip width = Spacing threshold

The factor phi is researched and calculated in the strip processing equipment analytically by FEM simulation as well as empirically, depending on the strip tension and strip thickness. In FIG. 5, the relationship is illustrated. With decreasing strip width, the strip can be spacing between the stabilizing unit and the air knife nozzle is increased (see Figure 4), because, based on the reduced strip width, corrugated strip not stress distribution or optimal asymmetric shape, because achieves the strip stabilized with a slight disadvantage. Based on the stress difference with respect to the strip thickness , elastic deformation occurs. The stress relating to the thickness of the thin plate takes the form of a transverse strip deformation (horizontal arc) above the limit value.

Local change of the stress distribution for sheet thickness due to an external force influence of the strip stabilizing unit, depending on the function passed illustrated, as seen in the strip running direction, 0 of the strip width. 75 times to 1 . It is shown up to 75 times the interval.

Vibration of the steel strip, if those that is based on, for example non-circular operation stabilization role in the zinc vessel, up to 1 from the strip spacing of the stabilizing portion is typically a nozzle gap from air knife nozzles. When it is 5m, under the control of the strip stabilizer, reduction of the strip oscillation is obtained as compared to the situation without the control of the strip stabilizer. As should be appreciated from FIG . Interval threshold of 5m is caused for many different typical strip width. If the strip stabilizer is present away from the air knife nozzle farther than this distance threshold, the vibration in the region of the air knife nozzle is not longer attenuated Runode, brought rather excited, thereby, the strip stabilizer despite the vibration damping in the region, the strip movement is increased inside the air knife nozzle, whereby the coating quality is lowered (FIG. 6).

The same is also true for the stabilization / smoothing strip shape. The interval below the distance threshold value, but good smoothing Ru obtained, thereon, the smoothing is either difficult or no longer possible.

Furthermore, the strip stabilizing coils acts always to alignment strip position, that has the following device is provided to combine the air knife nozzle and the strip stabilizer.

Compared to known systems, or stabilizing portion is aligned with the strip located in each or the effective positions are defined. The alignment is performed by specially provided alignment means.

Based on the special framework of air knife nozzles, stabilizer is fixed on the frame, thereby being fixed to the mechanical and can be reproducibly adjusted (Figure 3). Whereby alignment of the strip position or strip center, always equal among the stabilizing unit and the air knife nozzle.

Thereby , possible swiveling of the strip takes place during production, and no new definition of the zero position or the target position of the strip position is necessary. The air knife nozzle and the stabilization coil are mechanically synchronously aligned.

In summary, the following occurs:
1. Check maximum permitted spacing between the stabilizing action unit and air knife nozzle based on the physical relationship (principle based on Staint-Venant) for spacing ≦ phi * strip width.
2. The correction factor phi is 0 . 75 and 1 . Resulting from simulation and running experiments as a function of strip width between 75. Strip deformation in the lateral direction results from the instability based on small strip thickness. The reduced Ru strip width, this width, so not strongly Kanade, it occurs within an increase of possible spacing of the stabilizing portion from the air knife nozzle.
3. Integration of the strip stabilization coil into the air knife nozzle structure to improve alignment accuracy based on the mechanical connection of the stabilization coil and nozzle.
4). Strip stabilizing coils are always equally aligned regarding the connection of the air knife nozzle are aligned even with the inclined state or strip twisting.

1. . . . Stabilization coil . . . Steel strip 2. . . . Measuring system

Claims (16)

Strip position is detected, the strip running direction is arranged downstream of the air knife nozzle by a coil which acts on the steel strip through without electromagnetically contact, stabilizing force, Ru exerted on the strip in accordance with the detected strip position In the method of stabilizing a strip with a coating guided between air knife nozzles equipped with a melt immersion coating , the distance of the strip stabilization part from the air knife nozzle is adjusted to a value below the spacing threshold. the method of the interval threshold is calculated as a function of the strip width in consideration of factors phi, that factor phi, characterized in that it is calculated as a function of the strip thickness and the strip tension. The method according to claim 1, wherein the interval is adjusted to a value as small as possible and ideally zero. 3. A method according to claim 1 or 2, characterized in that the strip position is measured inside the coil array. 4. A method according to any one of the preceding claims, characterized in that the strip position is measured in the spatial vicinity of the coil array. 5. The method according to claim 1 , wherein the strip position is additionally measured at the top and bottom of the coil array. Spacing strip stabilizing unit from the air knife nozzle, the strip width in accordance with the actual strip width 1. 75-0 . 6. The method according to claim 1, wherein the value is 75 times. Strip position is detected as a local distribution of the strip intervals against the straight reference line that cotton strip width, any of claims 1 to 6 as far as its is characterized in that it represents the effective strip form as the effective measured quantity The method according to claim 1. Stabilizing force acts on the strip on the horizontal relative transport direction in accordance with the detected effective strip shape, the detected effective strip-shaped, the form of a strip shape without smooth waves transverse to the strip direction 8. The method of claim 7, wherein said smoothing is to a predetermined optimal target strip shape. Strip position is detected as the temporal change of the strip against the straight reference line interval of claims 1 to 6 as far as its is characterized in that it represents the effective vibration behavior of the strip which depends on the time as the effective measured quantity The method according to any one of the above. Stabilizing force, in accordance with the detected effective vibration behavior was the strip acts on the strip vertically against the particular transport direction, and characterized in that attenuated appropriately when the detected effective vibration behavior was strip the required The method according to claim 8. Measured strip position, as a distribution temporal and location changes over the strip width of the strip against the straight reference line spacing, strip vibration behavior of the shape represents as a function of time; is and stabilizing forces, the method according to any one of claims 7 to 10 and the vibration behavior simultaneously is strip-shaped smooth as much as necessary to ensure proper attenuation, characterized in that it acts to properly strip. At least one air knife nozzle for removing excess coating from the strip; a measuring device for detecting the strip position; an air knife in the direction of travel of the strip in order to generate a stabilizing force which acts on the steel strip in a contactless manner according to the detected strip position Ru and a strip stabilizing unit comprising an electromagnetic coil which is arranged downstream of the nozzle, the melt漬浸coating equipment for coating a strip with a coating, the strip stabilizer from the air knife nozzles (action) interval, The melting is characterized by being adjusted to a value equal to or less than the interval threshold, the interval threshold being calculated as a function of the strip width considering the factor phi , and the factor phi being calculated as a function of the strip thickness and strip tension. Dipping coating equipment. 13. The melt immersion coating apparatus according to claim 12, wherein the coils are disposed to be opposed to each other on the upper side and the lower side of the strip so as to change a distance from the air knife nozzle. 14. The melt immersion coating equipment according to claim 12 or 13, wherein the measuring device is arranged at or near the height of the coil and detects the strip position there. A plurality of coils are distributed over the width of the strip on the upper and / or lower side of the strip, respectively, and each externally located coil can be adjusted parallel to the plane of the strip on the penetrating strip side The melt immersion coating equipment according to any one of claims 12 to 14, wherein the equipment is disposed. Strip stabilizing unit and the measuring device, the molten漬浸coating equipment according to any one of claims 12 to 15, characterized in that at a distance constant from one another are mechanically connected.

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